| version 1.1.1.1, 1999/12/03 07:39:07 |
version 1.11, 2000/12/05 06:59:15 |
|
|
| /* $OpenXM: OpenXM/src/asir99/builtin/array.c,v 1.2 1999/11/23 07:14:14 noro Exp $ */ |
/* |
| |
* Copyright (c) 1994-2000 FUJITSU LABORATORIES LIMITED |
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* All rights reserved. |
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* |
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* FUJITSU LABORATORIES LIMITED ("FLL") hereby grants you a limited, |
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* non-exclusive and royalty-free license to use, copy, modify and |
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* redistribute, solely for non-commercial and non-profit purposes, the |
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* computer program, "Risa/Asir" ("SOFTWARE"), subject to the terms and |
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* conditions of this Agreement. For the avoidance of doubt, you acquire |
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* only a limited right to use the SOFTWARE hereunder, and FLL or any |
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* third party developer retains all rights, including but not limited to |
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* copyrights, in and to the SOFTWARE. |
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* |
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* (1) FLL does not grant you a license in any way for commercial |
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* purposes. You may use the SOFTWARE only for non-commercial and |
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* non-profit purposes only, such as academic, research and internal |
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* business use. |
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* (2) The SOFTWARE is protected by the Copyright Law of Japan and |
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* international copyright treaties. If you make copies of the SOFTWARE, |
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* with or without modification, as permitted hereunder, you shall affix |
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* to all such copies of the SOFTWARE the above copyright notice. |
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* (3) An explicit reference to this SOFTWARE and its copyright owner |
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* shall be made on your publication or presentation in any form of the |
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* results obtained by use of the SOFTWARE. |
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* (4) In the event that you modify the SOFTWARE, you shall notify FLL by |
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* e-mail at risa-admin@sec.flab.fujitsu.co.jp of the detailed specification |
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* for such modification or the source code of the modified part of the |
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* SOFTWARE. |
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* |
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* THE SOFTWARE IS PROVIDED AS IS WITHOUT ANY WARRANTY OF ANY KIND. FLL |
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* MAKES ABSOLUTELY NO WARRANTIES, EXPRESSED, IMPLIED OR STATUTORY, AND |
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* EXPRESSLY DISCLAIMS ANY IMPLIED WARRANTY OF MERCHANTABILITY, FITNESS |
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* FOR A PARTICULAR PURPOSE OR NONINFRINGEMENT OF THIRD PARTIES' |
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* RIGHTS. NO FLL DEALER, AGENT, EMPLOYEES IS AUTHORIZED TO MAKE ANY |
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* MODIFICATIONS, EXTENSIONS, OR ADDITIONS TO THIS WARRANTY. |
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* UNDER NO CIRCUMSTANCES AND UNDER NO LEGAL THEORY, TORT, CONTRACT, |
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* OR OTHERWISE, SHALL FLL BE LIABLE TO YOU OR ANY OTHER PERSON FOR ANY |
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* DIRECT, INDIRECT, SPECIAL, INCIDENTAL, PUNITIVE OR CONSEQUENTIAL |
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* DAMAGES OF ANY CHARACTER, INCLUDING, WITHOUT LIMITATION, DAMAGES |
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* ARISING OUT OF OR RELATING TO THE SOFTWARE OR THIS AGREEMENT, DAMAGES |
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* FOR LOSS OF GOODWILL, WORK STOPPAGE, OR LOSS OF DATA, OR FOR ANY |
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* DAMAGES, EVEN IF FLL SHALL HAVE BEEN INFORMED OF THE POSSIBILITY OF |
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* SUCH DAMAGES, OR FOR ANY CLAIM BY ANY OTHER PARTY. EVEN IF A PART |
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* OF THE SOFTWARE HAS BEEN DEVELOPED BY A THIRD PARTY, THE THIRD PARTY |
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* DEVELOPER SHALL HAVE NO LIABILITY IN CONNECTION WITH THE USE, |
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* PERFORMANCE OR NON-PERFORMANCE OF THE SOFTWARE. |
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* |
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* $OpenXM: OpenXM_contrib2/asir2000/builtin/array.c,v 1.10 2000/11/13 01:48:12 noro Exp $ |
| |
*/ |
| #include "ca.h" |
#include "ca.h" |
| #include "base.h" |
#include "base.h" |
| #include "parse.h" |
#include "parse.h" |
| #include "inline.h" |
#include "inline.h" |
| /* |
|
| |
#if 0 |
| #undef DMAR |
#undef DMAR |
| #define DMAR(a1,a2,a3,d,r) (r)=dmar(a1,a2,a3,d); |
#define DMAR(a1,a2,a3,d,r) (r)=dmar(a1,a2,a3,d); |
| */ |
#endif |
| |
|
| extern int Print; /* XXX */ |
extern int DP_Print; /* XXX */ |
| |
|
| |
void inner_product_mat_int_mod(Q **,int **,int,int,int,Q *); |
| |
void solve_by_lu_mod(int **,int,int,int **,int); |
| void solve_by_lu_gfmmat(GFMMAT,unsigned int,unsigned int *,unsigned int *); |
void solve_by_lu_gfmmat(GFMMAT,unsigned int,unsigned int *,unsigned int *); |
| int lu_gfmmat(GFMMAT,unsigned int,int *); |
int lu_gfmmat(GFMMAT,unsigned int,int *); |
| void mat_to_gfmmat(MAT,unsigned int,GFMMAT *); |
void mat_to_gfmmat(MAT,unsigned int,GFMMAT *); |
| Line 22 int gauss_elim_mod1(int **,int,int,int); |
|
| Line 73 int gauss_elim_mod1(int **,int,int,int); |
|
| int gauss_elim_geninv_mod(unsigned int **,int,int,int); |
int gauss_elim_geninv_mod(unsigned int **,int,int,int); |
| int gauss_elim_geninv_mod_swap(unsigned int **,int,int,unsigned int,unsigned int ***,int **); |
int gauss_elim_geninv_mod_swap(unsigned int **,int,int,unsigned int,unsigned int ***,int **); |
| void Pnewvect(), Pnewmat(), Psepvect(), Psize(), Pdet(), Pleqm(), Pleqm1(), Pgeninvm(); |
void Pnewvect(), Pnewmat(), Psepvect(), Psize(), Pdet(), Pleqm(), Pleqm1(), Pgeninvm(); |
| |
void Pnewbytearray(); |
| |
|
| void Pgeneric_gauss_elim_mod(); |
void Pgeneric_gauss_elim_mod(); |
| |
|
| Line 46 struct ftab array_tab[] = { |
|
| Line 98 struct ftab array_tab[] = { |
|
| {"generic_gauss_elim_mod",Pgeneric_gauss_elim_mod,2}, |
{"generic_gauss_elim_mod",Pgeneric_gauss_elim_mod,2}, |
| {"newvect",Pnewvect,-2}, |
{"newvect",Pnewvect,-2}, |
| {"newmat",Pnewmat,-3}, |
{"newmat",Pnewmat,-3}, |
| |
{"newbytearray",Pnewbytearray,-2}, |
| {"sepmat_destructive",Psepmat_destructive,2}, |
{"sepmat_destructive",Psepmat_destructive,2}, |
| {"sepvect",Psepvect,2}, |
{"sepvect",Psepvect,2}, |
| {"qsort",Pqsort,-2}, |
{"qsort",Pqsort,-2}, |
|
|
| |
|
| asir_assert(ARG0(arg),O_N,"newvect"); |
asir_assert(ARG0(arg),O_N,"newvect"); |
| len = QTOS((Q)ARG0(arg)); |
len = QTOS((Q)ARG0(arg)); |
| if ( len <= 0 ) |
if ( len < 0 ) |
| error("newvect : invalid size"); |
error("newvect : invalid size"); |
| MKVECT(vect,len); |
MKVECT(vect,len); |
| if ( argc(arg) == 2 ) { |
if ( argc(arg) == 2 ) { |
|
|
| *rp = vect; |
*rp = vect; |
| } |
} |
| |
|
| |
void Pnewbytearray(arg,rp) |
| |
NODE arg; |
| |
BYTEARRAY *rp; |
| |
{ |
| |
int len,i,r; |
| |
BYTEARRAY array; |
| |
unsigned char *vb; |
| |
char *str; |
| |
LIST list; |
| |
NODE tn; |
| |
|
| |
asir_assert(ARG0(arg),O_N,"newbytearray"); |
| |
len = QTOS((Q)ARG0(arg)); |
| |
if ( len < 0 ) |
| |
error("newbytearray : invalid size"); |
| |
MKBYTEARRAY(array,len); |
| |
if ( argc(arg) == 2 ) { |
| |
if ( !ARG1(arg) ) |
| |
error("newbytearray : invalid initialization"); |
| |
switch ( OID((Obj)ARG1(arg)) ) { |
| |
case O_LIST: |
| |
list = (LIST)ARG1(arg); |
| |
asir_assert(list,O_LIST,"newbytearray"); |
| |
for ( r = 0, tn = BDY(list); tn; r++, tn = NEXT(tn) ); |
| |
if ( r <= len ) { |
| |
for ( i = 0, tn = BDY(list), vb = BDY(array); tn; |
| |
i++, tn = NEXT(tn) ) |
| |
vb[i] = (unsigned char)QTOS((Q)BDY(tn)); |
| |
} |
| |
break; |
| |
case O_STR: |
| |
str = BDY((STRING)ARG1(arg)); |
| |
r = strlen(str); |
| |
if ( r <= len ) |
| |
bcopy(str,BDY(array),r); |
| |
break; |
| |
default: |
| |
if ( !ARG1(arg) ) |
| |
error("newbytearray : invalid initialization"); |
| |
} |
| |
} |
| |
*rp = array; |
| |
} |
| |
|
| void Pnewmat(arg,rp) |
void Pnewmat(arg,rp) |
| NODE arg; |
NODE arg; |
| MAT *rp; |
MAT *rp; |
|
|
| asir_assert(ARG0(arg),O_N,"newmat"); |
asir_assert(ARG0(arg),O_N,"newmat"); |
| asir_assert(ARG1(arg),O_N,"newmat"); |
asir_assert(ARG1(arg),O_N,"newmat"); |
| row = QTOS((Q)ARG0(arg)); col = QTOS((Q)ARG1(arg)); |
row = QTOS((Q)ARG0(arg)); col = QTOS((Q)ARG1(arg)); |
| if ( row <= 0 || col <= 0 ) |
if ( row < 0 || col < 0 ) |
| error("newmat : invalid size"); |
error("newmat : invalid size"); |
| MKMAT(m,row,col); |
MKMAT(m,row,col); |
| if ( argc(arg) == 3 ) { |
if ( argc(arg) == 3 ) { |
|
|
| t = mat[i]; |
t = mat[i]; |
| if ( i != j && (a = t[j]) ) |
if ( i != j && (a = t[j]) ) |
| for ( k = j, a = md - a; k <= n; k++ ) { |
for ( k = j, a = md - a; k <= n; k++ ) { |
| |
unsigned int tk; |
| /* t[k] = dmar(pivot[k],a,t[k],md); */ |
/* t[k] = dmar(pivot[k],a,t[k],md); */ |
| DMAR(pivot[k],a,t[k],md,t[k]) |
DMAR(pivot[k],a,t[k],md,tk) |
| |
t[k] = tk; |
| } |
} |
| } |
} |
| } |
} |
|
|
| return -1; |
return -1; |
| } |
} |
| |
|
| struct oEGT eg_mod,eg_elim,eg_chrem,eg_gschk,eg_intrat,eg_symb; |
struct oEGT eg_mod,eg_elim,eg_elim1,eg_elim2,eg_chrem,eg_gschk,eg_intrat,eg_symb; |
| |
|
| int generic_gauss_elim(mat,nm,dn,rindp,cindp) |
int generic_gauss_elim(mat,nm,dn,rindp,cindp) |
| MAT mat; |
MAT mat; |
| Line 706 int **rindp,**cindp; |
|
| Line 805 int **rindp,**cindp; |
|
| colstat = (int *)MALLOC_ATOMIC(col*sizeof(int)); |
colstat = (int *)MALLOC_ATOMIC(col*sizeof(int)); |
| wcolstat = (int *)MALLOC_ATOMIC(col*sizeof(int)); |
wcolstat = (int *)MALLOC_ATOMIC(col*sizeof(int)); |
| for ( ind = 0; ; ind++ ) { |
for ( ind = 0; ; ind++ ) { |
| if ( Print ) |
if ( DP_Print ) { |
| fprintf(asir_out,"."); |
fprintf(asir_out,"."); fflush(asir_out); |
| |
} |
| md = lprime[ind]; |
md = lprime[ind]; |
| get_eg(&tmp0); |
get_eg(&tmp0); |
| for ( i = 0; i < row; i++ ) |
for ( i = 0; i < row; i++ ) |
|
|
| } |
} |
| } else { |
} else { |
| if ( rank < rank0 ) { |
if ( rank < rank0 ) { |
| if ( Print ) |
if ( DP_Print ) { |
| fprintf(asir_out,"lower rank matrix; continuing...\n"); |
fprintf(asir_out,"lower rank matrix; continuing...\n"); |
| |
fflush(asir_out); |
| |
} |
| continue; |
continue; |
| } else if ( rank > rank0 ) { |
} else if ( rank > rank0 ) { |
| if ( Print ) |
if ( DP_Print ) { |
| fprintf(asir_out,"higher rank matrix; resetting...\n"); |
fprintf(asir_out,"higher rank matrix; resetting...\n"); |
| |
fflush(asir_out); |
| |
} |
| goto RESET; |
goto RESET; |
| } else { |
} else { |
| for ( j = 0; (j<col) && (colstat[j]==wcolstat[j]); j++ ); |
for ( j = 0; (j<col) && (colstat[j]==wcolstat[j]); j++ ); |
| if ( j < col ) { |
if ( j < col ) { |
| if ( Print ) |
if ( DP_Print ) { |
| fprintf(asir_out,"inconsitent colstat; resetting...\n"); |
fprintf(asir_out,"inconsitent colstat; resetting...\n"); |
| |
fflush(asir_out); |
| |
} |
| goto RESET; |
goto RESET; |
| } |
} |
| } |
} |
|
|
| else |
else |
| cind[l++] = j; |
cind[l++] = j; |
| get_eg(&tmp0); |
get_eg(&tmp0); |
| if ( gensolve_check(mat,*nm,*dn,rind,cind) ) |
if ( gensolve_check(mat,*nm,*dn,rind,cind) ) { |
| get_eg(&tmp1); |
get_eg(&tmp1); |
| add_eg(&eg_gschk,&tmp0,&tmp1); |
add_eg(&eg_gschk,&tmp0,&tmp1); |
| add_eg(&eg_gschk_split,&tmp0,&tmp1); |
add_eg(&eg_gschk_split,&tmp0,&tmp1); |
| if ( Print ) { |
if ( DP_Print ) { |
| print_eg("Mod",&eg_mod_split); |
print_eg("Mod",&eg_mod_split); |
| print_eg("Elim",&eg_elim_split); |
print_eg("Elim",&eg_elim_split); |
| print_eg("ChRem",&eg_chrem_split); |
print_eg("ChRem",&eg_chrem_split); |
| print_eg("IntRat",&eg_intrat_split); |
print_eg("IntRat",&eg_intrat_split); |
| print_eg("Check",&eg_gschk_split); |
print_eg("Check",&eg_gschk_split); |
| fflush(asir_out); |
fflush(asir_out); |
| |
} |
| |
return rank; |
| } |
} |
| return rank; |
|
| } |
} |
| } |
} |
| } |
} |
| } |
} |
| |
|
| |
int generic_gauss_elim_hensel(mat,nmmat,dn,rindp,cindp) |
| |
MAT mat; |
| |
MAT *nmmat; |
| |
Q *dn; |
| |
int **rindp,**cindp; |
| |
{ |
| |
MAT bmat,xmat; |
| |
Q **a0,**a,**b,**x,**nm; |
| |
Q *ai,*bi,*xi; |
| |
int row,col; |
| |
int **w; |
| |
int *wi; |
| |
int **wc; |
| |
Q mdq,q,s,u; |
| |
N tn; |
| |
int ind,md,i,j,k,l,li,ri,rank; |
| |
unsigned int t; |
| |
int *cinfo,*rinfo; |
| |
int *rind,*cind; |
| |
int count; |
| |
struct oEGT eg_mul,eg_inv,tmp0,tmp1; |
| |
|
| |
a0 = (Q **)mat->body; |
| |
row = mat->row; col = mat->col; |
| |
w = (int **)almat(row,col); |
| |
for ( ind = 0; ; ind++ ) { |
| |
md = lprime[ind]; |
| |
STOQ(md,mdq); |
| |
for ( i = 0; i < row; i++ ) |
| |
for ( j = 0, ai = a0[i], wi = w[i]; j < col; j++ ) |
| |
if ( q = (Q)ai[j] ) { |
| |
t = rem(NM(q),md); |
| |
if ( t && SGN(q) < 0 ) |
| |
t = (md - t) % md; |
| |
wi[j] = t; |
| |
} else |
| |
wi[j] = 0; |
| |
|
| |
rank = find_lhs_and_lu_mod(w,row,col,md,&rinfo,&cinfo); |
| |
a = (Q **)almat_pointer(rank,rank); /* lhs mat */ |
| |
MKMAT(bmat,rank,col-rank); b = (Q **)bmat->body; /* lhs mat */ |
| |
for ( j = li = ri = 0; j < col; j++ ) |
| |
if ( cinfo[j] ) { |
| |
/* the column is in lhs */ |
| |
for ( i = 0; i < rank; i++ ) { |
| |
w[i][li] = w[i][j]; |
| |
a[i][li] = a0[rinfo[i]][j]; |
| |
} |
| |
li++; |
| |
} else { |
| |
/* the column is in rhs */ |
| |
for ( i = 0; i < rank; i++ ) |
| |
b[i][ri] = a0[rinfo[i]][j]; |
| |
ri++; |
| |
} |
| |
|
| |
/* solve Ax+B=0; A: rank x rank, B: rank x ri */ |
| |
MKMAT(xmat,rank,ri); x = (Q **)(xmat)->body; |
| |
MKMAT(*nmmat,rank,ri); nm = (Q **)(*nmmat)->body; |
| |
/* use the right part of w as work area */ |
| |
/* ri = col - rank */ |
| |
wc = (int **)almat(rank,ri); |
| |
for ( i = 0; i < rank; i++ ) |
| |
wc[i] = w[i]+rank; |
| |
*rindp = rind = (int *)MALLOC_ATOMIC(rank*sizeof(int)); |
| |
*cindp = cind = (int *)MALLOC_ATOMIC((ri)*sizeof(int)); |
| |
|
| |
init_eg(&eg_mul); init_eg(&eg_inv); |
| |
for ( q = ONE, count = 0; ; count++ ) { |
| |
fprintf(stderr,"."); |
| |
/* wc = -b mod md */ |
| |
for ( i = 0; i < rank; i++ ) |
| |
for ( j = 0, bi = b[i], wi = wc[i]; j < ri; j++ ) |
| |
if ( u = (Q)bi[j] ) { |
| |
t = rem(NM(u),md); |
| |
if ( t && SGN(u) > 0 ) |
| |
t = (md - t) % md; |
| |
wi[j] = t; |
| |
} else |
| |
wi[j] = 0; |
| |
/* wc = A^(-1)wc; wc is normalized */ |
| |
get_eg(&tmp0); |
| |
solve_by_lu_mod(w,rank,md,wc,ri); |
| |
get_eg(&tmp1); |
| |
add_eg(&eg_inv,&tmp0,&tmp1); |
| |
/* x = x-q*wc */ |
| |
for ( i = 0; i < rank; i++ ) |
| |
for ( j = 0, xi = x[i], wi = wc[i]; j < ri; j++ ) { |
| |
STOQ(wi[j],u); mulq(q,u,&s); |
| |
subq(xi[j],s,&u); xi[j] = u; |
| |
} |
| |
get_eg(&tmp0); |
| |
for ( i = 0; i < rank; i++ ) |
| |
for ( j = 0; j < ri; j++ ) { |
| |
inner_product_mat_int_mod(a,wc,rank,i,j,&u); |
| |
addq(b[i][j],u,&s); |
| |
if ( s ) { |
| |
t = divin(NM(s),md,&tn); |
| |
if ( t ) |
| |
error("generic_gauss_elim_hensel:incosistent"); |
| |
NTOQ(tn,SGN(s),b[i][j]); |
| |
} else |
| |
b[i][j] = 0; |
| |
} |
| |
get_eg(&tmp1); |
| |
add_eg(&eg_mul,&tmp0,&tmp1); |
| |
/* q = q*md */ |
| |
mulq(q,mdq,&u); q = u; |
| |
if ( !(count % 2) && intmtoratm_q(xmat,NM(q),*nmmat,dn) ) { |
| |
for ( j = k = l = 0; j < col; j++ ) |
| |
if ( cinfo[j] ) |
| |
rind[k++] = j; |
| |
else |
| |
cind[l++] = j; |
| |
if ( gensolve_check(mat,*nmmat,*dn,rind,cind) ) { |
| |
fprintf(stderr,"\n"); |
| |
print_eg("INV",&eg_inv); |
| |
print_eg("MUL",&eg_mul); |
| |
fflush(asir_out); |
| |
return rank; |
| |
} |
| |
} |
| |
} |
| |
} |
| |
} |
| |
|
| int f4_nocheck; |
int f4_nocheck; |
| |
|
| int gensolve_check(mat,nm,dn,rind,cind) |
int gensolve_check(mat,nm,dn,rind,cind) |
|
|
| N u,unm,udn; |
N u,unm,udn; |
| int sgn,ret; |
int sgn,ret; |
| |
|
| |
if ( UNIN(md) ) |
| |
return 0; |
| row = mat->row; col = mat->col; |
row = mat->row; col = mat->col; |
| bshiftn(md,1,&t); |
bshiftn(md,1,&t); |
| isqrt(t,&s); |
isqrt(t,&s); |
|
|
| return 1; |
return 1; |
| } |
} |
| |
|
| |
/* mat->body = Q ** */ |
| |
|
| |
int intmtoratm_q(mat,md,nm,dn) |
| |
MAT mat; |
| |
N md; |
| |
MAT nm; |
| |
Q *dn; |
| |
{ |
| |
N t,s,b; |
| |
Q bound,dn0,dn1,nm1,q,tq; |
| |
int i,j,k,l,row,col; |
| |
Q **rmat; |
| |
Q **tmat; |
| |
Q *tmi; |
| |
Q *nmk; |
| |
N u,unm,udn; |
| |
int sgn,ret; |
| |
|
| |
if ( UNIN(md) ) |
| |
return 0; |
| |
row = mat->row; col = mat->col; |
| |
bshiftn(md,1,&t); |
| |
isqrt(t,&s); |
| |
bshiftn(s,64,&b); |
| |
if ( !b ) |
| |
b = ONEN; |
| |
dn0 = ONE; |
| |
tmat = (Q **)mat->body; |
| |
rmat = (Q **)nm->body; |
| |
for ( i = 0; i < row; i++ ) |
| |
for ( j = 0, tmi = tmat[i]; j < col; j++ ) |
| |
if ( tmi[j] ) { |
| |
muln(NM(tmi[j]),NM(dn0),&s); |
| |
remn(s,md,&u); |
| |
ret = inttorat(u,md,b,&sgn,&unm,&udn); |
| |
if ( !ret ) |
| |
return 0; |
| |
else { |
| |
if ( SGN(tmi[j])<0 ) |
| |
sgn = -sgn; |
| |
NTOQ(unm,sgn,nm1); |
| |
NTOQ(udn,1,dn1); |
| |
if ( !UNIQ(dn1) ) { |
| |
for ( k = 0; k < i; k++ ) |
| |
for ( l = 0, nmk = rmat[k]; l < col; l++ ) { |
| |
mulq(nmk[l],dn1,&q); nmk[l] = q; |
| |
} |
| |
for ( l = 0, nmk = rmat[i]; l < j; l++ ) { |
| |
mulq(nmk[l],dn1,&q); nmk[l] = q; |
| |
} |
| |
} |
| |
rmat[i][j] = nm1; |
| |
mulq(dn0,dn1,&q); dn0 = q; |
| |
} |
| |
} |
| |
*dn = dn0; |
| |
return 1; |
| |
} |
| |
|
| |
#define ONE_STEP1 if ( zzz = *s ) { DMAR(zzz,hc,*tj,md,*tj) } tj++; s++; |
| |
|
| |
void reduce_reducers_mod(mat,row,col,md) |
| |
int **mat; |
| |
int row,col; |
| |
int md; |
| |
{ |
| |
int i,j,k,l,hc,zzz; |
| |
int *t,*s,*tj,*ind; |
| |
|
| |
/* reduce the reducers */ |
| |
ind = (int *)ALLOCA(row*sizeof(int)); |
| |
for ( i = 0; i < row; i++ ) { |
| |
t = mat[i]; |
| |
for ( j = 0; j < col && !t[j]; j++ ); |
| |
/* register the position of the head term */ |
| |
ind[i] = j; |
| |
for ( l = i-1; l >= 0; l-- ) { |
| |
/* reduce mat[i] by mat[l] */ |
| |
if ( hc = t[ind[l]] ) { |
| |
/* mat[i] = mat[i]-hc*mat[l] */ |
| |
j = ind[l]; |
| |
s = mat[l]+j; |
| |
tj = t+j; |
| |
hc = md-hc; |
| |
k = col-j; |
| |
for ( ; k >= 64; k -= 64 ) { |
| |
ONE_STEP1 ONE_STEP1 ONE_STEP1 ONE_STEP1 |
| |
ONE_STEP1 ONE_STEP1 ONE_STEP1 ONE_STEP1 |
| |
ONE_STEP1 ONE_STEP1 ONE_STEP1 ONE_STEP1 |
| |
ONE_STEP1 ONE_STEP1 ONE_STEP1 ONE_STEP1 |
| |
ONE_STEP1 ONE_STEP1 ONE_STEP1 ONE_STEP1 |
| |
ONE_STEP1 ONE_STEP1 ONE_STEP1 ONE_STEP1 |
| |
ONE_STEP1 ONE_STEP1 ONE_STEP1 ONE_STEP1 |
| |
ONE_STEP1 ONE_STEP1 ONE_STEP1 ONE_STEP1 |
| |
ONE_STEP1 ONE_STEP1 ONE_STEP1 ONE_STEP1 |
| |
ONE_STEP1 ONE_STEP1 ONE_STEP1 ONE_STEP1 |
| |
ONE_STEP1 ONE_STEP1 ONE_STEP1 ONE_STEP1 |
| |
ONE_STEP1 ONE_STEP1 ONE_STEP1 ONE_STEP1 |
| |
ONE_STEP1 ONE_STEP1 ONE_STEP1 ONE_STEP1 |
| |
ONE_STEP1 ONE_STEP1 ONE_STEP1 ONE_STEP1 |
| |
ONE_STEP1 ONE_STEP1 ONE_STEP1 ONE_STEP1 |
| |
ONE_STEP1 ONE_STEP1 ONE_STEP1 ONE_STEP1 |
| |
} |
| |
for ( ; k >= 0; k-- ) { |
| |
if ( zzz = *s ) { DMAR(zzz,hc,*tj,md,*tj) } tj++; s++; |
| |
} |
| |
} |
| |
} |
| |
} |
| |
} |
| |
|
| |
/* |
| |
mat[i] : reducers (i=0,...,nred-1) |
| |
spolys (i=nred,...,row-1) |
| |
mat[0] < mat[1] < ... < mat[nred-1] w.r.t the term order |
| |
1. reduce the reducers |
| |
2. reduce spolys by the reduced reducers |
| |
*/ |
| |
|
| |
void pre_reduce_mod(mat,row,col,nred,md) |
| |
int **mat; |
| |
int row,col,nred; |
| |
int md; |
| |
{ |
| |
int i,j,k,l,hc,inv; |
| |
int *t,*s,*tk,*ind; |
| |
|
| |
#if 1 |
| |
/* reduce the reducers */ |
| |
ind = (int *)ALLOCA(row*sizeof(int)); |
| |
for ( i = 0; i < nred; i++ ) { |
| |
/* make mat[i] monic and mat[i] by mat[0],...,mat[i-1] */ |
| |
t = mat[i]; |
| |
for ( j = 0; j < col && !t[j]; j++ ); |
| |
/* register the position of the head term */ |
| |
ind[i] = j; |
| |
inv = invm(t[j],md); |
| |
for ( k = j; k < col; k++ ) |
| |
if ( t[k] ) |
| |
DMAR(t[k],inv,0,md,t[k]) |
| |
for ( l = i-1; l >= 0; l-- ) { |
| |
/* reduce mat[i] by mat[l] */ |
| |
if ( hc = t[ind[l]] ) { |
| |
/* mat[i] = mat[i]-hc*mat[l] */ |
| |
for ( k = ind[l], hc = md-hc, s = mat[l]+k, tk = t+k; |
| |
k < col; k++, tk++, s++ ) |
| |
if ( *s ) |
| |
DMAR(*s,hc,*tk,md,*tk) |
| |
} |
| |
} |
| |
} |
| |
/* reduce the spolys */ |
| |
for ( i = nred; i < row; i++ ) { |
| |
t = mat[i]; |
| |
for ( l = nred-1; l >= 0; l-- ) { |
| |
/* reduce mat[i] by mat[l] */ |
| |
if ( hc = t[ind[l]] ) { |
| |
/* mat[i] = mat[i]-hc*mat[l] */ |
| |
for ( k = ind[l], hc = md-hc, s = mat[l]+k, tk = t+k; |
| |
k < col; k++, tk++, s++ ) |
| |
if ( *s ) |
| |
DMAR(*s,hc,*tk,md,*tk) |
| |
} |
| |
} |
| |
} |
| |
#endif |
| |
} |
| |
/* |
| |
mat[i] : reducers (i=0,...,nred-1) |
| |
mat[0] < mat[1] < ... < mat[nred-1] w.r.t the term order |
| |
*/ |
| |
|
| |
void reduce_sp_by_red_mod(sp,redmat,ind,nred,col,md) |
| |
int *sp,**redmat; |
| |
int *ind; |
| |
int nred,col; |
| |
int md; |
| |
{ |
| |
int i,j,k,hc,zzz; |
| |
int *t,*s,*tj; |
| |
|
| |
/* reduce the spolys by redmat */ |
| |
for ( i = nred-1; i >= 0; i-- ) { |
| |
/* reduce sp by redmat[i] */ |
| |
if ( hc = sp[ind[i]] ) { |
| |
/* sp = sp-hc*redmat[i] */ |
| |
j = ind[i]; |
| |
hc = md-hc; |
| |
s = redmat[i]+j; |
| |
tj = sp+j; |
| |
for ( k = col-j; k >= 0; k-- ) { |
| |
if ( zzz = *s ) { DMAR(zzz,hc,*tj,md,*tj) } tj++; s++; |
| |
} |
| |
} |
| |
} |
| |
} |
| |
|
| |
#define ONE_STEP2 if ( zzz = *pk ) { DMAR(zzz,a,*tk,md,*tk) } pk++; tk++; |
| |
|
| int generic_gauss_elim_mod(mat,row,col,md,colstat) |
int generic_gauss_elim_mod(mat,row,col,md,colstat) |
| int **mat; |
int **mat; |
| int row,col,md; |
int row,col,md; |
| int *colstat; |
int *colstat; |
| { |
{ |
| int i,j,k,l,inv,a,rank; |
int i,j,k,l,inv,a,rank,zzz; |
| int *t,*pivot; |
int *t,*pivot,*pk,*tk; |
| |
|
| for ( rank = 0, j = 0; j < col; j++ ) { |
for ( rank = 0, j = 0; j < col; j++ ) { |
| for ( i = rank; i < row && !mat[i][j]; i++ ); |
for ( i = rank; i < row && !mat[i][j]; i++ ); |
|
|
| } |
} |
| pivot = mat[rank]; |
pivot = mat[rank]; |
| inv = invm(pivot[j],md); |
inv = invm(pivot[j],md); |
| for ( k = j; k < col; k++ ) |
for ( k = j, pk = pivot+k; k < col; k++, pk++ ) |
| if ( pivot[k] ) { |
if ( *pk ) { |
| DMAR(pivot[k],inv,0,md,pivot[k]) |
DMAR(*pk,inv,0,md,*pk) |
| } |
} |
| for ( i = rank+1; i < row; i++ ) { |
for ( i = rank+1; i < row; i++ ) { |
| t = mat[i]; |
t = mat[i]; |
| if ( a = t[j] ) |
if ( a = t[j] ) { |
| for ( k = j, a = md - a; k < col; k++ ) |
a = md - a; pk = pivot+j; tk = t+j; |
| if ( pivot[k] ) { |
k = col-j; |
| DMAR(pivot[k],a,t[k],md,t[k]) |
for ( ; k >= 64; k -= 64 ) { |
| } |
ONE_STEP2 ONE_STEP2 ONE_STEP2 ONE_STEP2 |
| |
ONE_STEP2 ONE_STEP2 ONE_STEP2 ONE_STEP2 |
| |
ONE_STEP2 ONE_STEP2 ONE_STEP2 ONE_STEP2 |
| |
ONE_STEP2 ONE_STEP2 ONE_STEP2 ONE_STEP2 |
| |
ONE_STEP2 ONE_STEP2 ONE_STEP2 ONE_STEP2 |
| |
ONE_STEP2 ONE_STEP2 ONE_STEP2 ONE_STEP2 |
| |
ONE_STEP2 ONE_STEP2 ONE_STEP2 ONE_STEP2 |
| |
ONE_STEP2 ONE_STEP2 ONE_STEP2 ONE_STEP2 |
| |
ONE_STEP2 ONE_STEP2 ONE_STEP2 ONE_STEP2 |
| |
ONE_STEP2 ONE_STEP2 ONE_STEP2 ONE_STEP2 |
| |
ONE_STEP2 ONE_STEP2 ONE_STEP2 ONE_STEP2 |
| |
ONE_STEP2 ONE_STEP2 ONE_STEP2 ONE_STEP2 |
| |
ONE_STEP2 ONE_STEP2 ONE_STEP2 ONE_STEP2 |
| |
ONE_STEP2 ONE_STEP2 ONE_STEP2 ONE_STEP2 |
| |
ONE_STEP2 ONE_STEP2 ONE_STEP2 ONE_STEP2 |
| |
ONE_STEP2 ONE_STEP2 ONE_STEP2 ONE_STEP2 |
| |
} |
| |
for ( ; k >= 0; k -- ) { |
| |
if ( zzz = *pk ) { DMAR(zzz,a,*tk,md,*tk) } pk++; tk++; |
| |
} |
| |
} |
| } |
} |
| rank++; |
rank++; |
| } |
} |
|
|
| pivot = mat[l]; |
pivot = mat[l]; |
| for ( i = 0; i < l; i++ ) { |
for ( i = 0; i < l; i++ ) { |
| t = mat[i]; |
t = mat[i]; |
| if ( a = t[j] ) |
if ( a = t[j] ) { |
| for ( k = j, a = md-a; k < col; k++ ) |
a = md-a; pk = pivot+j; tk = t+j; |
| if ( pivot[k] ) { |
k = col-j; |
| DMAR(pivot[k],a,t[k],md,t[k]) |
for ( ; k >= 64; k -= 64 ) { |
| } |
ONE_STEP2 ONE_STEP2 ONE_STEP2 ONE_STEP2 |
| |
ONE_STEP2 ONE_STEP2 ONE_STEP2 ONE_STEP2 |
| |
ONE_STEP2 ONE_STEP2 ONE_STEP2 ONE_STEP2 |
| |
ONE_STEP2 ONE_STEP2 ONE_STEP2 ONE_STEP2 |
| |
ONE_STEP2 ONE_STEP2 ONE_STEP2 ONE_STEP2 |
| |
ONE_STEP2 ONE_STEP2 ONE_STEP2 ONE_STEP2 |
| |
ONE_STEP2 ONE_STEP2 ONE_STEP2 ONE_STEP2 |
| |
ONE_STEP2 ONE_STEP2 ONE_STEP2 ONE_STEP2 |
| |
ONE_STEP2 ONE_STEP2 ONE_STEP2 ONE_STEP2 |
| |
ONE_STEP2 ONE_STEP2 ONE_STEP2 ONE_STEP2 |
| |
ONE_STEP2 ONE_STEP2 ONE_STEP2 ONE_STEP2 |
| |
ONE_STEP2 ONE_STEP2 ONE_STEP2 ONE_STEP2 |
| |
ONE_STEP2 ONE_STEP2 ONE_STEP2 ONE_STEP2 |
| |
ONE_STEP2 ONE_STEP2 ONE_STEP2 ONE_STEP2 |
| |
ONE_STEP2 ONE_STEP2 ONE_STEP2 ONE_STEP2 |
| |
ONE_STEP2 ONE_STEP2 ONE_STEP2 ONE_STEP2 |
| |
} |
| |
for ( ; k >= 0; k -- ) { |
| |
if ( zzz = *pk ) { DMAR(zzz,a,*tk,md,*tk) } pk++; tk++; |
| |
} |
| |
} |
| } |
} |
| l--; |
l--; |
| } |
} |
|
|
| DMAR(inv,m,0,md,t[k]) |
DMAR(inv,m,0,md,t[k]) |
| for ( j = k+1, m = md - t[k]; j < col; j++ ) |
for ( j = k+1, m = md - t[k]; j < col; j++ ) |
| if ( pivot[j] ) { |
if ( pivot[j] ) { |
| DMAR(m,pivot[j],t[j],md,t[j]) |
unsigned int tj; |
| |
|
| |
DMAR(m,pivot[j],t[j],md,tj) |
| |
t[j] = tj; |
| } |
} |
| } |
} |
| } |
} |
|
|
| return 1; |
return 1; |
| } |
} |
| |
|
| |
/* |
| |
Input |
| |
a: a row x col matrix |
| |
md : a modulus |
| |
|
| |
Output: |
| |
return : d = the rank of mat |
| |
a[0..(d-1)][0..(d-1)] : LU decomposition (a[i][i] = 1/U[i][i]) |
| |
rinfo: array of length row |
| |
cinfo: array of length col |
| |
i-th row in new a <-> rinfo[i]-th row in old a |
| |
cinfo[j]=1 <=> j-th column is contained in the LU decomp. |
| |
*/ |
| |
|
| |
int find_lhs_and_lu_mod(a,row,col,md,rinfo,cinfo) |
| |
unsigned int **a; |
| |
unsigned int md; |
| |
int **rinfo,**cinfo; |
| |
{ |
| |
int i,j,k,l,d; |
| |
int *rp,*cp; |
| |
unsigned int *t,*pivot; |
| |
unsigned int inv,m; |
| |
|
| |
*rinfo = rp = (int *)MALLOC_ATOMIC(row*sizeof(int)); |
| |
*cinfo = cp = (int *)MALLOC_ATOMIC(col*sizeof(int)); |
| |
for ( i = 0; i < row; i++ ) |
| |
rp[i] = i; |
| |
for ( k = 0, d = 0; k < col; k++ ) { |
| |
for ( i = d; i < row && !a[i][k]; i++ ); |
| |
if ( i == row ) { |
| |
cp[k] = 0; |
| |
continue; |
| |
} else |
| |
cp[k] = 1; |
| |
if ( i != d ) { |
| |
j = rp[i]; rp[i] = rp[d]; rp[d] = j; |
| |
t = a[i]; a[i] = a[d]; a[d] = t; |
| |
} |
| |
pivot = a[d]; |
| |
pivot[k] = inv = invm(pivot[k],md); |
| |
for ( i = d+1; i < row; i++ ) { |
| |
t = a[i]; |
| |
if ( m = t[k] ) { |
| |
DMAR(inv,m,0,md,t[k]) |
| |
for ( j = k+1, m = md - t[k]; j < col; j++ ) |
| |
if ( pivot[j] ) { |
| |
unsigned int tj; |
| |
DMAR(m,pivot[j],t[j],md,tj) |
| |
t[j] = tj; |
| |
} |
| |
} |
| |
} |
| |
d++; |
| |
} |
| |
return d; |
| |
} |
| |
|
| |
/* |
| |
Input |
| |
a : n x n matrix; a result of LU-decomposition |
| |
md : modulus |
| |
b : n x l matrix |
| |
Output |
| |
b = a^(-1)b |
| |
*/ |
| |
|
| |
void solve_by_lu_mod(a,n,md,b,l) |
| |
int **a; |
| |
int n; |
| |
int md; |
| |
int **b; |
| |
int l; |
| |
{ |
| |
unsigned int *y,*c; |
| |
int i,j,k; |
| |
unsigned int t,m,m2; |
| |
|
| |
y = (int *)MALLOC_ATOMIC(n*sizeof(int)); |
| |
c = (int *)MALLOC_ATOMIC(n*sizeof(int)); |
| |
m2 = md>>1; |
| |
for ( k = 0; k < l; k++ ) { |
| |
/* copy b[.][k] to c */ |
| |
for ( i = 0; i < n; i++ ) |
| |
c[i] = (unsigned int)b[i][k]; |
| |
/* solve Ly=c */ |
| |
for ( i = 0; i < n; i++ ) { |
| |
for ( t = c[i], j = 0; j < i; j++ ) |
| |
if ( a[i][j] ) { |
| |
m = md - a[i][j]; |
| |
DMAR(m,y[j],t,md,t) |
| |
} |
| |
y[i] = t; |
| |
} |
| |
/* solve Uc=y */ |
| |
for ( i = n-1; i >= 0; i-- ) { |
| |
for ( t = y[i], j =i+1; j < n; j++ ) |
| |
if ( a[i][j] ) { |
| |
m = md - a[i][j]; |
| |
DMAR(m,c[j],t,md,t) |
| |
} |
| |
/* a[i][i] = 1/U[i][i] */ |
| |
DMAR(t,a[i][i],0,md,c[i]) |
| |
} |
| |
/* copy c to b[.][k] with normalization */ |
| |
for ( i = 0; i < n; i++ ) |
| |
b[i][k] = (int)(c[i]>m2 ? c[i]-md : c[i]); |
| |
} |
| |
} |
| |
|
| void Pleqm1(arg,rp) |
void Pleqm1(arg,rp) |
| NODE arg; |
NODE arg; |
| VECT *rp; |
VECT *rp; |
|
|
| NTOQ(sum,sgn,*r); |
NTOQ(sum,sgn,*r); |
| } |
} |
| |
|
| |
/* (k,l) element of a*b where a: .x n matrix, b: n x . integer matrix */ |
| |
|
| |
void inner_product_mat_int_mod(a,b,n,k,l,r) |
| |
Q **a; |
| |
int **b; |
| |
int n,k,l; |
| |
Q *r; |
| |
{ |
| |
int la,lb,i; |
| |
int sgn,sgn1; |
| |
N wm,wma,sum,t; |
| |
Q aki; |
| |
int bil,bilsgn; |
| |
struct oN tn; |
| |
|
| |
for ( la = 0, i = 0; i < n; i++ ) { |
| |
if ( aki = a[k][i] ) |
| |
if ( DN(aki) ) |
| |
error("inner_product_int : invalid argument"); |
| |
else |
| |
la = MAX(PL(NM(aki)),la); |
| |
} |
| |
lb = 1; |
| |
sgn = 0; |
| |
sum= NALLOC(la+lb+2); |
| |
bzero((char *)sum,(la+lb+3)*sizeof(unsigned int)); |
| |
wm = NALLOC(la+lb+2); |
| |
wma = NALLOC(la+lb+2); |
| |
for ( i = 0; i < n; i++ ) { |
| |
if ( !(aki = a[k][i]) || !(bil = b[i][l]) ) |
| |
continue; |
| |
tn.p = 1; |
| |
if ( bil > 0 ) { |
| |
tn.b[0] = bil; bilsgn = 1; |
| |
} else { |
| |
tn.b[0] = -bil; bilsgn = -1; |
| |
} |
| |
_muln(NM(aki),&tn,wm); |
| |
sgn1 = SGN(aki)*bilsgn; |
| |
if ( !sgn ) { |
| |
sgn = sgn1; |
| |
t = wm; wm = sum; sum = t; |
| |
} else if ( sgn == sgn1 ) { |
| |
_addn(sum,wm,wma); |
| |
if ( !PL(wma) ) |
| |
sgn = 0; |
| |
t = wma; wma = sum; sum = t; |
| |
} else { |
| |
/* sgn*sum+sgn1*wm = sgn*(sum-wm) */ |
| |
sgn *= _subn(sum,wm,wma); |
| |
t = wma; wma = sum; sum = t; |
| |
} |
| |
} |
| |
GC_free(wm); |
| |
GC_free(wma); |
| |
if ( !sgn ) { |
| |
GC_free(sum); |
| |
*r = 0; |
| |
} else |
| |
NTOQ(sum,sgn,*r); |
| |
} |
| |
|
| void Pmul_mat_vect_int(arg,rp) |
void Pmul_mat_vect_int(arg,rp) |
| NODE arg; |
NODE arg; |
| VECT *rp; |
VECT *rp; |
|
|
| } |
} |
| /* exhausted */ |
/* exhausted */ |
| return 1; |
return 1; |
| |
} |
| |
|
| |
printqmat(mat,row,col) |
| |
Q **mat; |
| |
int row,col; |
| |
{ |
| |
int i,j; |
| |
|
| |
for ( i = 0; i < row; i++ ) { |
| |
for ( j = 0; j < col; j++ ) { |
| |
printnum((Num)mat[i][j]); printf(" "); |
| |
} |
| |
printf("\n"); |
| |
} |
| |
} |
| |
|
| |
printimat(mat,row,col) |
| |
int **mat; |
| |
int row,col; |
| |
{ |
| |
int i,j; |
| |
|
| |
for ( i = 0; i < row; i++ ) { |
| |
for ( j = 0; j < col; j++ ) { |
| |
printf("%d ",mat[i][j]); |
| |
} |
| |
printf("\n"); |
| |
} |
| } |
} |
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